朱宏偉 -- 清華大學材料學院教授、博士生導師 從事納米材料制備、結構表征和性能研究

朱宏偉

清華大學材料學院教授、博士生導師。從事納米材料制備、結構表征和性能研究。近年來承擔國家重點基礎研究發(fā)展計劃、國家自然科學基金、北京市科技計劃重大項目、教育部博士點基金等項目。曾獲國家自然科學二等獎和教育部自然科學一、二等獎。出版學術著作2部，在Science, Adv. Mater., Nano Lett., Energy Environ. Sci., Sci. Adv.和NPG Asia Mater.等期刊上發(fā)表論文200余篇。
【聯(lián)系方式】
Tel: +86-10-62797005
Fax: +86-10-62773637
E-mail: hongweizhu@tsinghua.edu.cn
實驗室主頁: http://cnmm.tsinghua.edu.cn/zhuhw/index.htm

個人主頁：MSE/zhuhongwei

教育背景

2003，清華大學，博士（材料加工工程）
1998，清華大學，學士（機械工程）

工作履歷

2009-      清華大學，教授
2008-2009  清華大學，副教授
2004-2008  University of Delaware/Louisiana State University (USA)，博士后
2003-2004  日本産業(yè)技術総合研究所，博士后

研究領域

納米材料宏觀結構組裝與功能調(diào)控
能源材料、環(huán)境材料、傳感材料

學術成果

1.T. T. Yang, D. Xie, Z. H. Li, H. W. Zhu*. Recent advances in wearable tactile sensors: materials, sensing mechanisms and device performance. Mater. Sci. Engin. R - Rep. 2017, 115, 1.
2.P. Z. Sun, R. Z. Ma*, X. Y. Bai, K. L. Wang, H. W. Zhu*, T. Sasaki. Single-layer nanosheets with exceptionally high and anisotropic hydroxyl ion conductivity. Sci. Adv. 2017, 3, e1602629.
3.P. Z. Sun, K. L. Wang, H. W. Zhu*. Recent developments in graphene-based membranes: structure, mass transport mechanism and potential applications. Adv. Mater. 2016, 28, 2287.
4.P. Z. Sun, R. Z. Ma*, W. Ma, J. H. Wu, K. L. Wang, T. Sasaki, H. W. Zhu*. Highly selective charge-guided ion transport through a hybrid membrane consisting of anionic graphene oxide and cationic hydroxide nanosheets superlattice units. NPG Asia Mater. 2016, 8, e259.
5.X. M. Li*, H. W. Zhu*. The graphene-semiconductor Schottky junction. Phys. Today 2016, 69, 46.
6.T. T. Yang, X. M. Li, X. Jiang, S. Y. Lin, J. C. Lao, J. D. Shi, Z. Zhen, Z. H. Li*, H. W. Zhu*. Structural engineering of gold thin films with channel cracks for ultrasensitive strain sensing. Mater. Horiz. 2016, 3, 248.
7.R. J. Zhang, N. Metoki, O. Sharabani-Yosef, H. W. Zhu*, N. Eliaz*. Hydroxyapatite/mesoporous graphene/single-walled carbon nanotubes freestanding flexible hybrid membranes for regenerative medicine. Adv. Funct. Mater. 2016 26, 7965.
8.X. M. Li, T. T. Yang, Y. Yang, J. Zhu, L. Li, F. E. Alam, K. L. Wang, H. Y. Chen, C. T. Lin*, Y. Fang*, H. W. Zhu*. Large-area ultrathin graphene films by single-step Marangoni self-assembly for highly sensitive strain sensing application. Adv. Funct. Mater. 2016, 26, 1322.
9.L. Zhang, Y. B. Li, X. Li, C. L. Li, R. J. Zhang, J. J. Delaunay, H. W. Zhu*. Solution-processed CuSbS2 thin film: a promising earth-abundant photocathode for efficient visible-light-driven hydrogen evolution. Nano Energy 2016, 28, 135.
10.T. T. Yang, W. Wang, H. Z. Zhang, X. M. Li, J. D. Shi, Y. J. He, Q. S. Zheng, Z. H. Li*, H. W. Zhu*. Tactile sensing system based on arrays of graphene woven microfabrics: electromechanical behavior and electronic skin application. ACS Nano 2015, 9, 10867.
11.X. M. Li, T. S. Zhao, H. W. Zhu*. Chapter 7: Quantum dot and heterojunction solar cells containing carbon nanomaterials in Carbon Nanomaterials for Advanced Energy Systems: Advances in Materials Synthesis and Device Applications. Ed. W. Lu, J. B. Baek, L. M. Dai. John Wiley & Sons (2015).
12.X. M. Li*, Z. Lv, H. W. Zhu*. Carbon/silicon heterojunction solar cells: State of the art and prospects. Adv. Mater. 2015, 27, 6549.
13.P. Z. Sun, Q. Chen, X. D. Li, H. Liu, K. L. Wang, M. L. Zhong, J. Q. Wei, D. H. Wu, R. Z. Ma, T. Sasaki, H. W. Zhu*. Highly efficient quasi-static water desalination using monolayer graphene oxide/titania hybrid laminates. NPG Asia Mater. 2015, 7, e162.
14.X. Li, X. B. Zang, X. M. Li, M. Zhu, Q. Chen, K. L. Wang, M. L. Zhong, J. Q. Wei, D. H. Wu, H. W. Zhu*. Hybrid heterojunction and solid state photoelectrochemical solar cells. Adv. Energy Mater. 2014, 4, 1400224.
15.Y. Wang, L. Wang, T. T. Yang, X. Li, X. B. Zang, M. Zhu, K. L. Wang, D. H. Wu, H. W. Zhu*. Wearable and highly sensitive graphene strain sensors for human motion monitoring. Adv. Funct. Mater. 2014, 24, 4666.
16.X. B. Zang, Q. Chen, P. X. Li, Y. J. He, X. Li, M. Zhu, X. M. Li, K. L. Wang, M. L. Zhong, D. H. Wu, H. W. Zhu*. Highly flexible and adaptable, all solid-state supercapacitors based on graphene woven fabric film electrodes. Small 2014, 10, 2583.
17.P. Z. Sun, F. Zheng, M. Zhu, Z. G. Song, K. L. Wang, M. L. Zhong, D. H. Wu, R. B. Little, Z. P. Xu, H. W. Zhu*. Selective trans-membrane transport of alkali and alkaline earth cations through graphene oxide membranes based on cation-π interaction. ACS Nano 2014, 8, 850.
18.P. Z. Sun, M. Zhu, K. L. Wang, M. L. Zhong, J. Q. Wei, D. H. Wu, Z. P. Xu, H. W. Zhu*. Selective ion penetration of graphene oxide membranes. ACS Nano 2013, 7, 428.
19.Y. X. Lin, X. M. Li, D. Xie, T. T. Feng, Y. Chen, R. Song, H. Tian, T. L. Ren, M. L. Zhong, K. L. Wang, H. W. Zhu*. Graphene/semiconductor heterojunction solar cells with modulated antireflection and graphene work function. Energy & Environ. Sci. 2013, 6, 108.
20.E. Z. Shi, H. B. Li*, L. Yang, L. H. Zhang, Z. Li, P. X. Li, Y. Y. Shang, S. T. Wu, X. M. Li, J. Q. Wei, K. L. Wang, H. W. Zhu*, D. H. Wu, Y. Fang, A. Y. Cao*. Colloidal antireflection coating improves graphene-silicon solar cells. Nano Lett. 2013, 13, 1776.
21.X. Li, R. J. Zhang, W. J. Yu, K. L. Wang, J. Q. Wei, D. H. Wu, A. Y. Cao, Z. H. Li, Y. Cheng, Q. S. Zheng, R. S. Ruoff, H. W. Zhu*. Stretchable and highly sensitive graphene-on-polymer strain sensors. Sci. Rep. 2012, 2, 870.
22.朱宏偉, 徐志平, 謝丹. 石墨烯: 結構、制備方法與性能表征. 北京: 清華大學出版社, 2011.
23.H. W. Zhu, B. Q. Wei. Macrostructures of carbon nanotubes. Encyclopedia of Nanosci. Nanotechnol., American Scientific Publishers, Ed. Hari Singh Nalwa. 2011, 16, 33 (Book chapter).
24.X. M. Li, H. W. Zhu*, K. L. Wang, A. Y. Cao, J. Q. Wei, C. Y. Li, Y. Jia, Z. Li, X. Li, D. H. Wu. Graphene-on-silicon Schottky junction solar cells. Adv. Mater. 2010, 22, 2743.
25.X. C. Gui, J. Q. Wei, K. L. Wang, A. Y. Cao, H. W. Zhu, Y. Jia, Q. K. Shu, D. H. Wu. Carbon nanotube sponges. Adv. Mater. 2010, 22, 617.
26.H. W. Zhu*, J. Q. Wei, K. L. Wang, D. H. Wu. Applications of carbon materials in photovoltaic solar cells. Sol. Energy Mater. Sol. Cells 2009, 93, 1461.
27.J. Z. Cai, L. Lu, W. J. Kong, H. W. Zhu, C. Zhang, B. Q. Wei, D. H. Wu, F. Liu. Pressure-induced transition in magnetoresistance of single-walled carbon nanotubes. Phys. Rev. Lett. 2006, 97, 026402.
28.H. W. Zhu, K. Suenaga, K. Mizuno, A. Hashimoto, K. Urita, K. Hata, S. Iijima. Atomic-resolution imaging of the nucleation points of single-walled carbon nanotubes. Small 2005, 1, 1180.
29.朱宏偉, 吳德海, 徐才錄. 碳納米管. 北京：機械工業(yè)出版社, 2003.
30.H. W. Zhu, C. L. Xu, D. H. Wu, B. Q. Wei, R. Vajtai, P. M. Ajayan. Direct synthesis of long single-walled carbon nanotube strands. Science 2002, 296, 884.

近日，清華大學材料學院朱宏偉課題組在石墨烯應用技術方面取得進展，1篇研究論文和2篇綜述文章分別發(fā)表在《美國化學學會·納米》（ACS Nano，影響因子：12.88）和《先進材料》（Advanced Materials，影響因子：17.49）上。文章第一作者分別為材料學院2012級博士生楊婷婷、孫鵬展和2013年畢業(yè)博士生李昕明。

石墨烯應用技術。

在《基于石墨烯編織網(wǎng)絡的傳感系統(tǒng)：機電行為與電子皮膚應用》（Tactile sensing system based on arrays of graphene woven microfabrics: electromechanical behavior and electronic skin application）（ACS Nano 2015, DOI: 10.1021/acsnano.5b03851）論文中，課題組提出了一種實現(xiàn)石墨烯高靈敏柔性應變傳感的新思路，將石墨烯與超彈超薄高分子材料復合形成柔性、輕薄似紋身的應變傳感器。通過構建傳感器陣列，實現(xiàn)了感知分布式壓力的電子皮膚功能，可穩(wěn)定可靠探測脈搏、語音等微弱生理信號，有望應用于移動醫(yī)療、可穿戴式設備等領域。

在《石墨烯滲透膜的研究進展：結構、傳質(zhì)機制及潛在應用》（Recent developments in graphene-based membranes: structure, mass transport mechanism and potential applications）（Adv. Mater. 2015, DOI: 10.1002/adma.201502595）一文中，圍繞石墨烯材料獨特的結構特點及其不同于傳統(tǒng)滲透膜材料的傳質(zhì)行為，課題組綜述了石墨烯滲透膜材料傳質(zhì)特性的相關實驗發(fā)現(xiàn)和理論結果，對其在過濾、分離、脫鹽、質(zhì)子交換及能量存儲等方面的應用進行了展望。通過總結本課題組及其它小組的研究成果，系統(tǒng)分析了三種石墨烯膜材料（理想石墨烯單晶膜、納米孔石墨烯和氧化石墨烯滲透膜）的傳質(zhì)特性、潛在應用及其面臨的機遇和挑戰(zhàn)。

《碳/硅異質(zhì)結太陽能電池的研究現(xiàn)狀與展望》（Carbon/silicon heterojunction solar cells: State of the art and prospects）（Adv. Mater. 2015, 27, 6549–6574）一文，結合課題組提出的碳/半導體異質(zhì)結光電模型，綜述了碳/硅異質(zhì)結太陽能電池的研發(fā)過程和最新研究進展，以增強太陽能電池性能為目標，介紹了幾種關鍵的電學、光學設計技術（包括化學改性、界面鈍化、減反涂層和表面毛化等），展望了碳/硅異質(zhì)結的潛在應用和未來發(fā)展趨勢。該光電模型有望在便攜式器件和輕型薄膜產(chǎn)品中發(fā)揮多重關鍵作用，在諸如智能手機、移動設備和醫(yī)學監(jiān)控設備中做為新型能源。

朱宏偉課題組近年來專注于石墨烯材料的可控制備與性能研究，學術問題涵蓋結構設計、光電轉(zhuǎn)換、柔性器件、吸附過濾等方面。通過調(diào)控石墨烯與其它材料的表/界面相互作用，探索了石墨烯在納米能源、納米探測和納米環(huán)境應用中的性能。

上述研究得到了北京市科技計劃重大項目、國家自然科學基金、新型陶瓷與精細工藝國家重點實驗室自主科研基金等項目的資助。